Disclosed is technology in that a clip structure formed of an inexpensive and light metallic material to easily performing soldering on a corresponding metal and to reduce costs of a semiconductor package and to reduce the weight of the semiconductor package. The composite clip structure bent at a predetermined angle and being in charge of electrical connection between components in a semiconductor package includes a main metal layer formed of a conductive material with a predetermined thickness, and a lower functional layer formed below the main metal layer and formed of a different type of metal from a metallic component of the main metal layer, wherein the lower functional layer is attached to the main metal layer to be integrated thereinto, and wherein the main metal layer is formed of a single metal containing a largest amount of aluminum (Al) or a metal mixture containing a largest amount of Al.

A semiconductor device includes a semiconductor element, leads, and an encapsulation resin covering a portion of each of the leads and the semiconductor element. Each of the leads includes an external connection portion projecting from a side surface of the encapsulation resin. The external connection portion of at least one of the leads has opposite ends in a width-wise direction that extends along the side surface of the encapsulation resin. The external connection portion includes two recesses arranged toward a center in the width-wise direction from the opposite ends. The two recesses extend from a distal surface toward the encapsulation resin. The opposite ends in the width-wise direction define an end connection part. The external connection portion includes a part between the two recesses defining a center connection part.

A semiconductor device includes a semiconductor element, leads, and an encapsulation resin covering a portion of each of the leads and the semiconductor element. Each of the leads includes an external connection portion projecting from a side surface of the encapsulation resin. The external connection portion of at least one of the leads has opposite ends in a width-wise direction that extends along the side surface of the encapsulation resin. The external connection portion includes two recesses arranged toward a center in the width-wise direction from the opposite ends. The two recesses extend from a distal surface toward the encapsulation resin. The opposite ends in the width-wise direction define an end connection part. The external connection portion includes a part between the two recesses defining a center connection part.

An electrical circuit body includes a power semiconductor element joined to one face of a conductor plate, a sheet member including an insulating layer joined to the other face of the conductor plate, a sealing member integrally sealing the sheet member, the conductor plate, and the power semiconductor element in a state where a face, of the sheet member, opposite to a face joined to the conductor plate is exposed, and a cooling member bonded to the opposite face of the sheet member via a heat conduction member, wherein the sealing member has a recess along an outer edge of the sheet member on a surface where the sheet member is exposed, the recess being located outside the sheet member.

A semiconductor device includes a semiconductor element and a first connection member. The semiconductor element includes a substrate and an electrode pad. The substrate includes a transistor formation region, in which a transistor is formed and which is shaped to be non-quadrangular. The electrode pad is located on the transistor formation region. The first connection member is connected to the electrode pad at one location. The electrode pad is arranged to cover a center of gravity of the transistor formation region in a plan view of the electrode pad. In the plan view, a connection region in which the first connection member is connected to the electrode pad includes a center of gravity position of the transistor formation region.

A semiconductor device includes a semiconductor element and a first connection member. The semiconductor element includes a substrate and an electrode pad. The substrate includes a transistor formation region, in which a transistor is formed and which is shaped to be non-quadrangular. The electrode pad is located on the transistor formation region. The first connection member is connected to the electrode pad at one location. The electrode pad is arranged to cover a center of gravity of the transistor formation region in a plan view of the electrode pad. In the plan view, a connection region in which the first connection member is connected to the electrode pad includes a center of gravity position of the transistor formation region.

A method for fabricating a semiconductor device includes providing a semiconductor die, arranging an electrical connector over the semiconductor die, the electrical connector including a conductive core, an absorbing feature arranged on a first side of the conductive core, and a solder layer arranged on a second side of the conductive core, opposite the first side and facing the semiconductor die, and soldering the electrical connector onto the semiconductor die by heating the solder layer with a laser, wherein the laser irradiates the absorbing feature and absorbed energy is transferred from the absorbing feature through the conductive core to the solder layer.

Provided is a semiconductor module comprising a semiconductor chip, a lead frame including a chip connection portion configured to connect the lead frame to the semiconductor chip, and a bonding member configured to connect the chip connection portion and the semiconductor chip, wherein the semiconductor chip includes a semiconductor substrate, an active portion provided on the semiconductor substrate, and a transverse protective film provided above the active portion and provided to traverse the active portion in a top view, wherein the chip connection portion includes a center portion which covers a center of the transverse protective film in a top view and a first cut-out portion provided from a first end side of the chip connection portion towards the center portion.

Provided is a semiconductor module comprising a semiconductor chip, a lead frame including a chip connection portion configured to connect the lead frame to the semiconductor chip, and a bonding member configured to connect the chip connection portion and the semiconductor chip, wherein the semiconductor chip includes a semiconductor substrate, an active portion provided on the semiconductor substrate, and a transverse protective film provided above the active portion and provided to traverse the active portion in a top view, wherein the chip connection portion includes a center portion which covers a center of the transverse protective film in a top view and a first cut-out portion provided from a first end side of the chip connection portion towards the center portion.

A lead frame extends from inside a sealing resin to outside the sealing resin, and is placed to make contact with a main surface of an insulating sheet opposite to a heat dissipation plate. A semiconductor element is jointed to at least a portion of a main surface of the lead frame opposite to the insulating sheet within the sealing resin. The surface of the insulating sheet in contact with the lead frame is inclined and lowered to move away from the lead frame in an end region including at least a portion of an outermost end in plan view of the insulating sheet. The sealing resin enters a region between the lead frame and the insulating sheet in the end region. The lead frame is flat at least within the sealing resin.